System and method using natural language processing to synthesize and build infrastructure platforms

ABSTRACT

Embodiments of the invention are directed to a system, method, or computer program product structured for synthesizing and building infrastructure platforms. In some embodiments, the system is structured for performing a natural language synthesis of a proposed upgrade to existing infrastructure platform(s), where the natural language synthesis includes analyzing, using natural language processing, code of the proposed upgrade; generating a trust score indicating a predicted likelihood of success from results of the natural language synthesis; in response to the trust score being above a threshold, identifying, using natural language processing, inactive code in the platform(s); generating a build automation script for deploying the proposed upgrade to create upgraded infrastructure platform(s) that exclude the inactive code; executing the build automation script; capturing data from the build automation script execution; and using the result of the build automation script execution and the captured data to refine the natural language synthesis.

CROSS-REFERENCE TO RELATED APPLICATION

The present application is a continuation of co-pending U.S. patentapplication Ser. No. 16/933,612, of the same title and filed on Jul. 20,2020, which is assigned to the assignee hereof and the contents thereofare hereby expressly incorporated by reference.

BACKGROUND

An entity may operate a system that hosts one or more platforms. Theplatform(s) may be configured to perform one or more functions. A givenplatform may also host or partially host a large number of applications,each directed to performing additional and, many times, specializedfunctions. From time to time, however, the platform(s) may need to beupgraded. For example, an upgrade to a platform may be needed to expandthe functions that can be performed by the platform. However, upgradinga platform may be a difficult and lengthy process, particularly when aplatform is hosting applications with functions that may be disrupted ifthere are issues with the platform being upgraded. As such, there is aneed for a system that could measure the likelihood of success for agiven platform upgrade.

BRIEF SUMMARY

The following presents a simplified summary of one or more embodimentsof the invention in order to provide a basic understanding of suchembodiments. This summary is not an extensive overview of allcontemplated embodiments and is intended to neither identify key orcritical elements of all embodiments, nor delineate the scope of any orall embodiments. Its sole purpose is to present some concepts of one ormore embodiments in a simplified form as a prelude to the more detaileddescription that is presented later.

Embodiments of the present invention address these and/or other needs byproviding systems, computer program products, and methods forsynthesizing and building infrastructure platforms. In some instances,the system comprises: a memory device with computer-readable programcode stored thereon; a communication device; and a processing deviceoperatively coupled to the memory device and communication device,wherein the processing device is configured to execute thecomputer-readable program code to: perform a natural language synthesisof a proposed upgrade to one or more existing infrastructure platforms,wherein the natural language synthesis comprises analyzing, usingnatural language processing, code of the proposed upgrade; generate atrust score from results of the natural language synthesis, wherein thetrust score indicates a predicted likelihood of success for the proposedupgrade; in response to the trust score being above a threshold,identify, using natural language processing, inactive code in the one ormore existing infrastructure platforms; generate a build automationscript for deploying the proposed upgrade to create one or more upgradedinfrastructure platforms that exclude the inactive code; execute thebuild automation script; capture data from a result of the buildautomation script execution; and use the result of the build automationscript execution and the captured data to refine the natural languagesynthesis.

In some embodiments, the invention is further configured to: build anexecution plan from the results of the natural language synthesis; andgenerate a report from the execution plan, wherein the report includesinstructions on deploying the proposed upgrade written in plainlanguage, and wherein the build automation script is at least partiallybased on the report.

In some embodiments, or in combination with any of the previousembodiments, analyzing, using natural language processing, the code ofthe proposed upgrade comprises: comparing commands used in the code ofthe proposed upgrade to commands used in the one or more existinginfrastructure platforms; determining whether the commands of theproposed upgrade code match the commands of the one or more existinginfrastructure platforms; and if one or more commands of the proposedupgrade code do not match the commands of the one or more existinginfrastructure platforms, determining how frequently the one or morecommands are used in the proposed upgrade code.

In some embodiments, or in combination with any of the previousembodiments, analyzing, using natural language processing, the code ofthe proposed upgrade comprises: comparing commands used in the code ofthe proposed upgrade to commands used in the one or more existinginfrastructure platforms; determining whether permissions of theproposed upgrade commands match permissions of the existinginfrastructure platform commands; and if one or more permissions of theproposed upgrade commands do not match the permissions of the existinginfrastructure platform commands, determining how frequently the one ormore permissions are used in the proposed upgrade code.

In some embodiments, or in combination with any of the previousembodiments, analyzing, using natural language processing, the code ofthe proposed upgrade comprises: comparing database connections in thecode of the proposed upgrade to database connections in the one or moreexisting infrastructure platforms; determining whether the databaseconnections of the proposed upgrade code match the database connectionsof the one or more existing infrastructure platforms; and if one or moredatabase connections of the proposed upgrade code do not match thedatabase connections of the one or more existing infrastructureplatforms, determining a ratio of the one or more database connectionsto a total number of database connections of the proposed upgrade code.

In some embodiments, or in combination with any of the previousembodiments, analyzing, using natural language processing, the code ofthe proposed upgrade comprises: determining a list of third-partyproducts included on the one or more existing infrastructure platforms;for each third-party product, determining whether a same version, alesser version, or a higher version of the third-party product isincluded in the proposed upgrade; if the same version or the higherversion of one or more third-party products is included in the proposedupgrade, determining whether the one or more third-party products arecompatible with the code of the proposed upgrade; and if at least one ofthe one or more third-party products is not compatible with the code ofthe proposed upgrade, determining how frequently the at least onethird-party product is used in the proposed upgrade code compared to howfrequently the at least one third-party product is used in the one ormore existing infrastructure platforms.

In some embodiments, or in combination with any of the previousembodiments, generating the trust score from the results of the naturallanguage synthesis comprises: determining, based on the results of thenatural language synthesis, whether the code of the proposed upgrademeets a plurality of weighted criteria, wherein each weighted criterionis associated with a weighted value; and using the weighted values ofthe met criteria to generate the trust score.

In some embodiments, or in combination with any of the previousembodiments, capturing the data from the result of the build automationscript execution comprises, in response to one or more post-deploymenterrors in the deployment of the proposed upgrade, capturing the one ormore post-deployment errors and one or more parameters of the proposedupgrade that caused the one or more post-deployment errors.

In some embodiments, or in combination with any of the previousembodiments, capturing the data from the result of the build automationscript execution comprises, in response to the deployment of theproposed upgrade being a success, capturing one or more parameters ofthe proposed upgrade relating to the success.

The features, functions, and advantages that have been discussed may beachieved independently in various embodiments of the present inventionor may be combined with yet other embodiments, further details of whichcan be seen with reference to the following description and drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

Having thus described embodiments of the invention in general terms,reference will now be made to the accompanying drawings, where:

FIG. 1 illustrates a block network architecture diagram illustrating asystem environment 100 for synthesizing and building infrastructureplatforms, in accordance with some embodiments of the invention;

FIG. 2 illustrates a block diagram 200 of an entity system, inaccordance with some embodiments of the invention;

FIG. 3 illustrates a block diagram 300 of a user device, in accordancewith some embodiments of the invention;

FIG. 4 illustrates a block diagram 400 of a deployment evaluationsystem, in accordance with some embodiments of the invention;

FIG. 5 illustrates a high-level process flow 500 for synthesizing andbuilding infrastructure platforms, in accordance with some embodimentsof the invention;

FIG. 6 illustrates a high-level process flow 600 for performing anatural language synthesis of a proposed upgrade, in accordance withsome embodiments of the invention; and

FIG. 7 illustrates a representation of a graphical user interface 700for display on a user device, in accordance with some embodiments of theinvention.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION

Embodiments of the present invention now may be described more fullyhereinafter with reference to the accompanying drawings, in which some,but not all, embodiments of the invention are shown. Indeed, theinvention may be embodied in many different forms and should not beconstrued as limited to the embodiments set forth herein; rather, theseembodiments are provided so that this disclosure may satisfy applicablelegal requirements. Like numbers refer to like elements throughout.Where possible, any terms expressed in the singular form herein aremeant to also include the plural form and vice versa, unless explicitlystated otherwise. Also, as used herein, the term “a” and/or “an” shallmean “one or more,” even though the phrase “one or more” is also usedherein. Furthermore, when it is said herein that something is “based on”something else, it may be based on one or more other things as well. Inother words, unless expressly indicated otherwise, as used herein “basedon” means “based at least in part on” or “based at least partially on.”

In some embodiments, an “entity” or “enterprise” as used herein may beany institution employing information technology resources and,particularly, technology infrastructure configured for large scaleprocessing of electronic files, electronic technology event data, andrecords, as well as performing/processing associated technologyactivities. In some instances, the entity's technology systems comprisemultiple technology applications across multiple distributed technologyplatforms for large scale processing of technology activity files andelectronic records. As such, the entity may be any institution, group,association, financial institution, merchant, establishment, company,union, authority, or the like, employing technology resources.

As described herein, a “user” is an individual associated with anentity. In some embodiments, a “user” may be an employee (e.g., a buildengineer, a technology operator/technician, an associate, a projectmanager, an information technology (IT) specialist, a manager, anadministrator, an internal operations analyst, or the like) of theentity or enterprise affiliated with the entity who is capable ofoperating the systems described herein. In some embodiments, a “user”may not be a direct employee of the entity but rather an indirectemployee, such as a contractor or third-party services provider. In someembodiments, a user may be or include a system performing one or moretasks described herein.

A “customer” is an individual, group, or system associated with theentity. In some embodiments, a customer may be an individual, group, orsystem having past relationships, current relationships, or potentialfuture relationships with an entity. For example, in the instances wherethe entity is a resource entity or a merchant, financial institution, orthe like, a customer may be an individual, group, or system with one ormore relationships, affiliations, or accounts with the entity (e.g., themerchant, the financial institution, or the like). In some instances, acustomer may not be a direct customer of the entity but may instead beany individual, group, or system who has a relationship with the directcustomer of the entity.

A “technology resource” or “account” may be the relationship that thecustomer has with the entity. Examples of technology resources include adeposit account, such as a transactional account (e.g. a bankingaccount), a savings account, an investment account, a money marketaccount, a time deposit, a demand deposit, a pre-paid account, a creditaccount, customer information, or the like. The technology resource oraccount may be associated with and/or maintained by an entity. Thetechnology resource or account may also be associated with technologyinfrastructure such that the resource or account may be accessed,modified, or acted upon by the customer electronically, for example,using transaction terminals, user devices, merchant systems, and thelike. In some embodiments, the entity may provide one or more technologyinstruments or financial instruments to the customer for executingresource transfer activities or financial transactions. In someembodiments, the technology instruments/financial instruments, likeelectronic tokens, credit cards, debit cards, checks, loyalty cards,user device applications, account identifiers, routing numbers,passcodes, and the like, may be associated with one or more resources oraccounts of the customer. In some embodiments, the entity may representa vendor or a merchant with whom the customer engages in financialtransactions (e.g., resource transfers like purchases, payments,returns, enrolling in merchant accounts and the like) or non-financialtransactions (for resource transfers associated with loyalty programsand the like), either online or in physical stores or merchantlocations.

As used herein, a “user interface” may be an interface for user-machineinteraction. In some embodiments, the user interface comprises agraphical user interface (GUI). A GUI is a type of user interface thatallows users to interact with electronic devices via graphical icons andvisual indicators, such as graphical widgets, graphical icons, andvisual indicators (e.g., secondary notation), as opposed to using onlytext via the command line. In some instances, a GUI may include bothgraphical elements and text elements. A GUI may also incorporate one ormore elements that facilitate communication using one or morecommunication mediums, such as tactile communication (e.g.,communication via a touchscreen, keyboard, and the like), audiocommunication, textual communication, and/or video communication (e.g.,gestures detected by a camera). That said, the GUIs may be configuredfor audio, visual, and/or textual communication, and may be configuredto receive input and/or provide output using one or more user devicecomponents and/or external auxiliary/peripheral devices such as adisplay, a speaker, a microphone, a touchscreen, a camera, a GPS device,a keypad, a mouse, and/or the like. The graphical user interface may beconfigured to be presented on one or more display devices associatedwith user devices, entity systems, auxiliary user devices, processingsystems, and the like.

An electronic activity, also referred to as a “technology activity” or a“customer activity,” such as a “resource transfer” or “transaction,” mayrefer to any activities or communications between a customer or entityand a financial institution, between the customer and the entity,activities or communication between multiple entities, communicationbetween technology applications, and the like. A resource transfer mayrefer to a payment, a processing of funds, a purchase of goods orservices, a return of goods or services, a payment transaction, a credittransaction, or other interactions involving a customer's resource oraccount. In the context of a financial institution or a resource entitysuch as a merchant, a resource transfer may refer to one or more of: atransfer of resources/funds between financial accounts (also referred toas “resources”), a deposit of resources/funds into a financial accountor resource (e.g., depositing a check), a withdrawal of resources orfunds from a financial account, a sale of goods and/or services,initiating an automated teller machine (ATM) or online banking session,an account balance inquiry, a rewards transfer, opening a bankapplication on a customer's computer or mobile device, a user accessingtheir e-wallet, applying one or more coupons to purchases, or any otherinteraction involving the customer and/or a customer's personal devicethat invokes or that is detectable by or associated with the financialinstitution. A resource transfer may also include one or more of thefollowing: renting, selling, and/or leasing goods and/or services (e.g.,groceries, stamps, tickets, DVDs, vending machine items, and the like);making payments (e.g., paying monthly bills and the like); loading moneyonto stored value cards (SVCs) and/or prepaid cards; donating tocharities; and/or the like. Unless specifically limited by the context,a “resource transfer,” a “transaction,” a “transaction event,” or a“point of transaction event” may refer to any customer activity(financial or non-financial activity) initiated between a customer and aresource entity (such as a merchant), between the customer and afinancial institution, or any combination thereof.

In accordance with embodiments of the invention, the term “electroniccommunication” may refer to a communication associated with a user orwith a customer, typically received, viewed, and/or transmitted via acommunication channel. In some embodiments, electronic communicationsmay be associated with user and/or customer communications relating totravel, appointments, etc. (e.g., non-financial communications). In someembodiments, electronic communications may be associated with userand/or customer communications relating to user financial statements(e.g., savings statements, shareholder notices, etc.), bill payments,account notifications, communications requiring actions to be performedby the user or customer, communications triggering resource/accountactivities, documents to be signed by the user or customer, etc. (e.g.,financial communications). In some embodiments, communication channelsmay comprise cellular, audio, email, cellular messaging, website, mobileapplication notifications, and the like.

Under current systems and methods, an entity may operate a system thathas one or more infrastructure platforms that are configured to performone or more functions, including hosting various applications. Eachapplication may be directed to performing one or more additionalfunctions, which may also be specialized functions. Applications may bedeployed on the infrastructure platform(s) by the entity or by partnersof the entity, such as merchant partners in electronic communicationwith systems of the entity. In some cases, infrastructure platform(s)may host a large number of applications, for example, more than onehundred applications on a given platform. Additionally, a platform mayalso operate through the use of a large number of scripts. As anillustration, a platform may include over 10,000 scripts. Some of thesescripts may be inactive, for instance, due to changing uses of theplatform or due to previous upgrades to the platform that have renderedolder scripts obsolete.

From time to time, a platform may need to be upgraded. For example,upgrading a platform may allow the platform to perform new functionsand/or host more or different types of applications. Upgrading aplatform may also be used to address issues in the platform, such assecurity issues or compatibility issues. However, upgrading a platformmay be complicated by the functions that the platform performs and theapplications that the platform hosts. More specifically, if a platformupgrade is unsuccessful or results in one or more errors, thefunctionality of the platform may be disrupted, which may in turndisrupt the functionality of the applications hosted on the platform. Assuch, platform upgrades may take a long time to perform, such as over ayear, as build engineers test the proposed upgrade and verify that theplatform will still be operational when the upgrade is deployed.Additionally, the time that a platform upgrade takes may be artificiallyinflated by application owners who seek reassurance that the platformupgrade will not disrupt the functionality of their applications.

Further, as noted above, a platform may include a large amount ofinactive and obsolete code. However, due to the large number of scriptsused to create a platform and the large number of hours it would take toreview all of them, it may be nearly impossible for a build engineer toidentify the inactive code from the active code. Additionally, deployinga proposed upgrade may require experienced build engineers to performlarge numbers of tasks, as the deployment process may be too difficultfor less experienced engineers to take on.

Accordingly, embodiments of the present disclosure are directed to asystem and a method for using natural language processing to synthesizeand build infrastructure platforms. More specifically, a deploymentevaluation system may perform a natural language synthesis on the codeof a proposed upgrade to identify various components of the code, suchas executable commands, permissions, external database connections, andthe like. The natural language synthesis may also include simulating anexecution of the proposed upgrade. The deployment evaluation system maythen use the results of the natural language synthesis to output a trustscore indicating a predicted likelihood that the proposed upgrade willbe a success. If the trust score is too low, the deployment evaluationsystem may initiate a repair process to attempt to fix at least some ofthe issues causing the low score. On the other hand, if the trust scoreis high enough, the deployment evaluation system may again use naturallanguage processing to identify active code from inactive code in thetarget platform(s) to be upgraded. The deployment evaluation system maythen generate a script or a series of scripts that will facilitate thedeployment of the proposed upgrade while omitting the identifiedinactive code. Additionally, the deployment evaluation system maysimulate a deployment of the proposed upgrade and, from the simulationresults, generate a deployment report detailing recommended actions theshould be performed in deploying a proposed upgrade, where the report iswritten in plain, less technical language. The report may be sent to abuild engineer, who may perform at least some of the recommendedactions, as well as used in generating the deployment script.

Regardless of whether the deployment is a success or a failure, thedeployment evaluation system may use the results of the deployment todetermine what aspects of the proposed upgrade caused the success orfailure. The deployment evaluation system may also examine proposedupgrades with low trust scores to determine what caused the low trustscore. This data may all be fed back into the processes of performingthe natural language synthesis, generating the trust score, identifyingthe inactive code, and the like, in order to more accurately predict thelikelihood of successfully deploying future upgrades and to generatebetter and more complete deployment reports.

As such, the systems described herein provide a user with a metric andprediction of whether a new build or upgrade is likely to succeed orfail in advance. In turn, this may allow the system and/or the user toredress and reduce multiple failures via proactive recognition of issuesand remediation. Additionally, the systems described herein may providereal-time notifications of detected issues, such as compatibilityissues, to the build engineers or other users preparing the upgrade.Both the metric and the ability to identify and address predictedfailures in advance may increase the trust that owners of applicationshosted on the platform may have with the proposed upgrade. Therefore,all of this may result in lowered testing times and faster upgradedeployment, such as upgrades occurring in three months. With fasterupgrades that have fewer issues, a platform may therefore be made morefunctional, more compatible, and more secure. The systems describedherein may also remove some of the need for build engineers to performmanual review of commands and scripts, thereby allowing them to performother tasks, such as working on additional future upgrades.

Moreover, as noted above, the systems described herein include automaticidentification of inactive code, a function that could not feasibly beperformed by a user. Thus, an upgrade to a platform may migrate onlyactive code to the new environment. This may free up storage space forother functions in the server systems on which the platform(s) areoperated. In addition, as also discussed above, the systems describedherein may output deployment reports that are written ineasy-to-understand language such that less experienced build engineersmay carry out recommended actions provided therein. With lessexperienced engineers better able to work on upgrades, this may allow anupgrade to be further deployed more quickly and with potentiallyimproved functionality, as more experienced build engineers may then beavailable to work on the more difficult aspects of the proposed upgrade.

Referring to FIG. 1, a block diagram illustrating a system environmentconfigured for synthesizing and building infrastructure platforms isillustrated, in accordance with some embodiments of the invention. Asillustrated, the system environment 100 includes an entity system 102 inoperative communication with a deployment evaluation system 104 and auser device 106. As such, the entity system 102, the deploymentevaluation system 104, and the user device 106 are configured to senddata to and receive data from each other, such as data relating topredicting how successful a proposed platform upgrade will be anddetermining a plan for deploying the upgrade. The system environmentalso includes a proposed upgrade database 108 with which the entitysystem 102, the deployment evaluation system 104, and the user device106 may electronically communicate.

Typically, the entity system 102, the deployment evaluation system 104,the user device 106, and the proposed upgrade database 108 are inelectronic communication with each other via the network 101, which maybe the internet, an intranet, or the like. The network 101 is configuredto establish an operative connection between otherwise incompatibledevices, for example, by establishing a communication channel,automatically and in real time, between the entity system 102, thedeployment evaluation system 104, the user device 106, and/or theproposed upgrade database 108. In this regard, the wirelesscommunication channel may further comprise near field communication(NFC), communication via radio waves, communication through theinternet, communication via electromagnetic waves, and the like. In FIG.1, the network 101 may include a local area network (LAN), a wide areanetwork (WAN), a global area network (GAN), and/or a near fieldcommunication (NFC) network. Accordingly, the network 101 may providefor wireline, wireless, or a combination of wireline and wirelesscommunication between devices in the network 101.

The entity system 102 is associated with the entity and configured tooperate one or more infrastructure platforms adapted to perform one ormore functions, including hosting applications created by users of theentity and/or third-parties associated with the entity. Additionally,the entity system 102 may store information relating to the relationshipa customer has with the entity, such as customer account information.The components of the entity system 102, its features, and its functionswill be described in further detail below and with respect to FIG. 2, inparticular.

The deployment evaluation system 104 is configured to evaluate thelikelihood that a proposed upgrade to a platform or platforms of theentity system 102 will be successful. As such, the deployment evaluationsystem 104 is configured to gather information about the proposedupgrade from the proposed upgrade database 108, as well as informationabout the platform(s) being upgraded from the entity system 102.Additionally, if the predicted likelihood of success is high enough, thedeployment evaluation system 104 is configured to determine a plan fordeploying the proposed upgrade and for facilitating the proposedupgrade. The components of the deployment evaluation system 104, itsfeatures, and its functions will be described in further detail belowand with respect to FIG. 4, in particular.

A user device 106 may comprise a personal computing device, such as adesktop computer or laptop computer. Alternatively, in some cases, theuser device 106 may comprise a mobile communications device, such as acellular telecommunications device (e.g., a smartphone or mobile phone),a personal digital assistant (PDA), a mobile internet accessing device,or the like. The user device 106 is configured to connect to the network101, as well as transmit and receive information over the network 101.As an illustration, the user device 106 may be used to construct theproposed upgrade, in whole or in part, and store the proposed upgrade inthe proposed upgrade database 108 (e.g., store scripts configured tooperate the proposed upgrade when executed). As another illustration,the user device 106 may receive information from the deploymentevaluation system 104, such as a report on a likelihood of success ofthe proposed upgrade or a deployment report describing actions thatshould be performed, either by the user or by a system (e.g., thedeployment evaluation system), in order to make the proposed upgradeready for deployment. The components of the user device 106, itsfeatures, and its functions will be described in further detail belowand with respect to FIG. 3, in particular.

The proposed upgrade database 108 is configured to store a proposedupgrade to one or more infrastructure platforms of the entity system102. For instance, as discussed above, the entity system 102 may operateone or more software infrastructure platforms configured to performcertain functions. However, an upgrade to one or more platform may beneeded in order to expand the functions performed by the platform(s),address compatibility issues in the platform(s), address security issuesin the platform(s) or otherwise generally improve the security of theplatform(s), and so on. Thus, the proposed upgrade (e.g.,computer-readable code, including executable commands), as well asinformation about the proposed upgrade (e.g., metadata on the proposedupgrade), may be stored in the proposed upgrade database 108. Forexample, in some cases, the proposed upgrade database 108 may storepermissions needed to operate the proposed upgrade, information onexternal databases used by the proposed upgrade, compatibilityinformation for the proposed upgrade (e.g., which versions ofthird-party software are used in the proposed upgrade), and/or the like.In some instances, the proposed upgrade database 108 may be a singledata storage unit, as shown in FIG. 1, while in other instances, theproposed upgrade database 108 may be comprised of one or more networkeddata storage units.

FIG. 2 illustrates a block diagram 200 of the entity system 102, inaccordance with some embodiments of the invention. As illustrated inFIG. 2, the entity system 102 may include a communication device 202, aprocessing device 204, and a memory device 206 having one or moreinfrastructure platform(s) 210 and a processing datastore 212 storedtherein. As shown, the processing device 204 is operatively connected toand configured to control and cause the communication device 202 and thememory device 206 to perform one or more functions. In some embodiments,the infrastructure platform(s) 210 comprises computer-readableinstructions or computer-readable code that when executed by theprocessing device 204 cause the processing device 204 to perform one ormore functions that, together, create the operable infrastructureplatform(s). For example, the infrastructure platform(s) 210 may includea computer-readable program code having one or more executable portions.It will be understood that the infrastructure platform(s) 210 may beexecutable to initiate, perform, complete, and/or facilitate one or moreportions of any embodiments described and/or contemplated herein.

The communication device 202 may generally include a modem, server,transceiver, and/or other device for communicating with other devices onthe network 101. In some embodiments, the communication device 202 maybe a communication interface having one or more communication devicesconfigured to communicate with one or more devices on the network 101,such as the deployment evaluation system 104, the user device 106, andthe proposed upgrade database 108. The communicative connection to oneor more devices on the network 101 may be via a wired or wirelessconnection. In this regard, the wireless communication channel maycomprise near field communication (NFC), communication via radio waves,communication through the internet, communication via electromagneticwaves, communication via applicable cellular systems of wirelesstelephone networks, and the like.

Additionally, referring to the entity system 102 illustrated in FIG. 2,the processing device 204 may generally refer to a device or combinationof devices having circuitry used for implementing the communicationand/or logic functions of the processing device 204. For example, theprocessing device 204 may include a control unit; a digital signalprocessor device; a microprocessor device; and various analog-to-digitalconverters, digital-to-analog converters, and other support circuitsand/or combinations of the foregoing. Control and signal processing ofthe entity system 102 may be allocated between these processing devicesaccording to their respective capabilities. The processing device 204may further include functionality to operate one or more softwareprograms based on computer-readable instructions 208 thereof, which maybe stored in the memory device 206.

As the phrase is used herein, a processing device may be “configured to”perform a certain function in a variety of ways, including, for example,by having one or more general-purpose circuits perform the function byexecuting particular computer-executable program code embodied in acomputer-readable medium and/or by having one or moreapplication-specific circuits perform the function. The processingdevice 204 may be configured to use the network communication interfaceof the communication device 202 to transmit and/or receive data and/orcommands to and/or from the other devices/systems connected to thenetwork 101.

The memory device 206 within the entity system 102 may generally referto a device or combination of devices that store one or more forms ofcomputer-readable media for storing data and/or computer-executableprogram code/instructions. For example, the memory device 206 mayinclude any computer memory that provides an actual or virtual space totemporarily or permanently store data and/or commands provided to theprocessing device 204 when it carries out the functions describedherein.

The entity system 102 may further include a data repository 214comprising authentication data 216, account data 218, and platform data220. The processing device 204 may utilize the authentication data 216to validate authentication credentials of customers attempting, forexample, to check a balance of an account held with the entity. Theaccount data 218 may reflect current account or technology resource datafor various customers of the entity. Alternatively, the entity system102 may store different account data 218 that a user or customer of theentity may request to access, such as employment information that anemployee user may attempt to access.

The platform data 220 includes data on the infrastructure platform(s)210. For example, the platform data 220 may include computer-readablecode that is executed to generate the infrastructure platform(s) 210.This may include a list of executable commands included in thecomputer-readable code. Alternatively or additionally, the platform data220 may include metadata on the infrastructure platform(s) 210; data onthe operation of the infrastructure platform(s) 210, such as permissionsneeded to operate the infrastructure platform(s) 210 and information onexternal databases used by the infrastructure platform(s) 210;compatibility information for the infrastructure platform(s) 210; and/orthe like.

In some embodiments, the infrastructure platform(s) 210 may comprisecomputer-readable instructions associated with one or moreinfrastructure platforms that perform one or more functions. Eachinfrastructure platform may also host one or more applications, whereeach application performs additional functions and/or supplements thefunctions of the infrastructure platform. An application may be providedby sources internal to the entity (e.g., developed by build engineers ofthe entity) or provided by a third party (e.g., a merchant partner ofthe entity). Alternatively, in some embodiments, the infrastructureplatform(s) 210 may be stored in the processing datastore 212. In someembodiments, the infrastructure platform(s) 210 comprisecomputer-readable instructions that, when executed by the processingdevice 204, cause the processing device 204 to perform one or morefunctions and/or transmit control instructions to other components ordevices to generate the one or more infrastructure platforms. Theinfrastructure platform(s) 210 may be implemented as a centralizedmodule as shown in FIG. 2, in some instances, or the infrastructureplatform(s) 210 may be implemented as a series of connectedapplications, software architectures, and/or the like that together formthe infrastructure platform(s), in other instances.

FIG. 3 illustrates a block diagram 300 of the user device 106, inaccordance with some embodiments of the invention. As illustrated inFIG. 3, the user device 106 may include a communication device 302; aprocessing device 304; and a memory device 306 having an platformupgrade application 310, an evaluation check application 312, and aprocessing datastore 314 stored therein. As shown, the processing device304 is operatively connected to and configured to control and cause thecommunication device 302 and the memory device 306 to perform one ormore functions. In some embodiments, the platform upgrade application310 and/or evaluation check application 312 comprises computer-readableinstructions or computer-readable code that when executed by theprocessing device 304 cause the processing device 304 to perform one ormore functions. For example, the platform upgrade application 310 and/orevaluation check application 312 may include computer-readable programcode having one or more executable portions. It will be understood thatthe platform upgrade application 310 and/or evaluation check application312 may be executable to initiate, perform, complete, and/or facilitateone or more portions of any embodiments described and/or contemplatedherein.

The communication device 302 may generally include a modem, server,transceiver, and/or other device for communicating with other devices onthe network 101. In some embodiments, the communication device 302 maybe a communication interface having one or more communication devicesconfigured to communicate with one or more devices on the network 101,such as the entity system 102, the deployment evaluation system 104, andthe proposed upgrade database 108. As such, the communicative connectionof the communication device 302 may be a wired or wireless connectionsimilar to the implementation of the communication device 202 of theblock diagram 200 of the entity system 102.

Referring to the user device 106 illustrated in FIG. 3, the processingdevice 304 may generally refer to a device or combination of deviceshaving circuitry used for implementing the communication and/or logicfunctions of the processing device 304. In this way, the processingdevice 304 may be configured similarly to the processing device 204 ofthe block diagram 200 of the entity system 102. Additionally, theprocessing device 304 may further include functionality to operate oneor more software programs based on computer-readable instructions 308thereof, which may be stored in the memory device 306, such as theplatform upgrade application 310 and the evaluation check application312. The processing device 304 may be configured to use the networkcommunication interface of the communication device 302 to transmitand/or receive data and/or commands to and/or from the otherdevices/systems connected to the network 101, similar to the processingdevice 204 of the entity system 102.

The memory device 306 within the user device 106 may generally refer toa device or combination of devices that store one or more forms ofcomputer-readable media for storing data and/or computer-executableprogram instructions. For example, the memory device 306 may include anycomputer memory that provides an actual or virtual space to temporarilyor permanently store data and/or commands provided to the processingdevice 304 when it carries out the functions described herein, similarto the memory device 206 of the block diagram 200 of the entity system102.

In some embodiments, the platform upgrade application 310 may comprisecomputer-readable instructions associated with building a platformupgrade, or the computer-readable instructions associated with buildinga platform upgrade may be stored in the processing datastore 314. Morespecifically, the platform upgrade application 310 may be structured tofacilitate the user in building a proposed upgrade to one or more of theplatforms operated by the entity system 102. Thus, in some embodiments,the platform upgrade application 310 may be structured as one or moreframeworks or architectures that allow the user or a group of users tobuild the proposed upgrade, in whole or in part, such by facilitatingthe writing and compiling of scripts that will form the proposedupgrade. For example, while the environment 100 shown in FIG. 1 shows asingle user device 106, in some embodiments the environment 100 mayinclude a number of user devices 106, each associated with a userworking on building the platform upgrade via the platform upgradeapplication 310 of the user device 106. In some embodiments, theplatform upgrade application 310 comprises computer-readableinstructions that, when executed by the processing device 304, cause theprocessing device 304 to perform one or more functions and/or transmitcontrol instructions to other components or devices to build orfacilitate the building of a platform upgrade.

It should also be understood that, in some cases, the platform upgradeapplication 310 may be implemented as a centralized module as shown inFIG. 3, while, in other cases, the platform upgrade application 310 maybe implemented as a series of connected applications, frameworks,architectures, and/or the like that together allow the user to build thesystem upgrade in whole or in part. Further, in some cases, the platformupgrade application 310 may be or include one or more applications,frameworks, architectures, and/or the like that can be used to createupgrades or other computer-readable code for a variety of platformsand/or functionalities, and/or, in some cases, the platform upgradeapplication 310 may be or include one or more applications, frameworks,architectures, and/or the like that can be used to create upgradesspecifically for the platform(s) of the entity system 102.

In some embodiments, the evaluation check application 312 may comprisecomputer-readable instructions associated with performing one or moresteps for checking the evaluation of a proposed upgrade to one or moreplatforms of the entity system 102, where the evaluation and the processof preparing the evaluation is described in further detail below withreference to the deployment evaluation system 104. Alternatively, insome embodiments, the computer-readable instructions associated withperforming the one or more steps for checking the evaluation of aproposed upgrade may be stored in the processing datastore 314. In someembodiments, the evaluation check application 312 comprisescomputer-readable instructions that, when executed by the processingdevice 304, cause the processing device 304 to perform one or morefunctions and/or transmit control instructions to other components ordevices to perform the one or more steps for checking the evaluation ofa proposed upgrade. In some cases, the evaluation check application 312may be implemented through an existing application, such as through aweb browser that the user can use to access an intranet site throughwhich the evaluation can be displayed. In other cases, the evaluationcheck application 312 may be implemented as a specialized application,such as an application specially designed for facilitating a user inchecking the evaluation of a proposed upgrade. The evaluation displayedto the user via the evaluation check application 312 may include a trustscore, a breakdown of the trust score, a deployment report, and/or thelike, as described in further detail below. For example, the evaluationdisplayed to the user via the evaluation check application 312 mayinclude one more GUIs similar to the interface shown in FIG. 7, which isalso described in further detail below.

FIG. 4 illustrates a block diagram 400 of the deployment evaluationsystem 104, in accordance with some embodiments of the invention. Asillustrated in FIG. 4, the deployment evaluation system 104 may includea communication device 402; a processing device 404; and a memory device406 having a natural language synthesis application 410, a trust scoreapplication 412, an active code segregator application 414, anexperiences interpreter application 416, and a processing datastore 418stored therein. As shown, the processing device 404 is operativelyconnected to and configured to control and cause the communicationdevice 402 and the memory device 406 to perform one or more functions.In some embodiments, the natural language synthesis application 410, thetrust score application 412, the active code segregator application 414,and/or the experiences interpreter application 416 comprisescomputer-readable instructions or computer-readable code that whenexecuted by the processing device 404 cause the processing device 404 toperform one or more functions. For example, the natural languagesynthesis application 410, the trust score application 412, the activecode segregator application 414, and/or the experiences interpreterapplication 416 may include computer-readable program code having one ormore executable portions. It will be understood that the naturallanguage synthesis application 410, the trust score application 412, theactive code segregator application 414, and/or the experiencesinterpreter application 416 may be executable to initiate, perform,complete, and/or facilitate one or more portions of any embodimentsdescribed and/or contemplated herein.

The communication device 402 may generally include a modem, server,transceiver, and/or other device for communicating with other devices onthe network 101. In some embodiments, the communication device 402 maybe a communication interface having one or more communication devicesconfigured to communicate with one or more devices on the network 101,such as the entity system 102, the user device 106, and the proposedupgrade database 108. As such, the communicative connection of thecommunication device 402 may be a wired or wireless connection similarto the implementation of the communication device 202 of the blockdiagram of the entity system 102.

Referring to the deployment evaluation system 104 illustrated in FIG. 4,the processing device 404 may generally refer to a device or combinationof devices having circuits used for implementing the communicationand/or logic functions of the processing device 404. In this way, theprocessing device 404 may be configured similarly to the processingdevice 204 of the block diagram 200 of the entity system 102.Additionally, the processing device 404 may further includefunctionality to operate one or more software programs based oncomputer-readable instructions 408 thereof, which may be stored in thememory device 406, such as the natural language synthesis application410, the trust score application 412, the active code segregatorapplication 414, and the experiences interpreter application 416. Theprocessing device 404 may also be configured to use the networkcommunication interface of the communication device 402 to transmitand/or receive data and/or commands to and/or from the otherdevices/systems connected to the network 101, similar to the processingdevice 204 of the entity system 102.

The memory device 406 within the deployment evaluation system 104 maygenerally refer to a device or combination of devices that store one ormore forms of computer-readable media for storing data and/orcomputer-executable program instructions. For example, the memory device406 may include any computer memory that provides an actual or virtualspace to temporarily or permanently store data and/or commands providedto the processing device 404 when it carries out the functions describedherein, similar to the memory device 206 of the block diagram 200 of theentity system 102.

The deployment evaluation system 104 may further include an evaluationdata repository 420 comprising evaluation data 422. The processingdevice 404 may utilize the evaluation data 422 to evaluate thelikelihood of success in deploying the proposed upgrade that is storedin the proposed upgrade database 108 to one or more platforms of theentity system 102. The processing device 404 may further utilize theevaluation data 422 to determine a deployment plan for the proposedupgrade. In this way, in some embodiments, the evaluation data 422 mayinclude data about the platform(s) of the entity system 102 to beupgraded, such as data about the computer-readable code of theplatform(s), metadata about the platform(s), and data about theoperation of the platform(s), gathered from the infrastructureplatform(s) 210 and/or the platform data 220 of the block diagram 200 ofthe entity system 102. Similarly, in some embodiments, the evaluationdata 422 may include data about the proposed upgrade, such as data aboutthe computer-readable code of the proposed upgrade, metadata about theproposed upgrade, and data about the predicted and/or tested operationof the proposed upgrade, gathered from the proposed upgrade database108. Alternatively, in some embodiments, the deployment evaluationsystem 104 may not gather data about the platform(s) and the proposedupgrade and may instead use the data directly stored by theinfrastructure platform(s) 210 and the platform data 220 of the blockdiagram 200 of the entity system 102 and stored by the proposed upgradedatabase 108.

Alternatively, or additionally, in some embodiments, the evaluation data422 may include data created by the natural language synthesisapplication 410, the trust score application 412, the active codesegregator application 41, and/or the experiences interpreterapplication 416. For example, the evaluation data 422 may includedeployment reports on proposed upgrades generated by the naturallanguage synthesis application 410, trust scores generated by the trustscore application 412, identifications of active versus inactive code onthe platform(s) to be upgraded that are determined by the active codesegregator application 414, and the experiences documented by theexperiences interpreter application 416, as discussed in further detailbelow.

In some embodiments, the natural language synthesis application 410 maycomprise computer-readable instructions associated with one or morenatural language synthesis steps, or the computer-readable instructionsassociated with one or more natural language synthesis steps may bestored in the processing datastore 418. The natural language synthesisapplication 410 may be embodied within one or more of the trust scoreapplication 412, active code segregator application 414, or experiencesinterpreter application 416, in some instances, or one or more of thetrust score application 412, active code segregator application 414, orexperiences interpreter application 416 may be embodied within thenatural language synthesis application 410, in some instances. In someembodiments, the natural language synthesis application 410 comprisescomputer-readable instructions that, when executed by the processingdevice 404, cause the processing device 404 to perform one or morefunctions and/or transmit control instructions to other components ordevices to perform the one or more natural language synthesis stepsdescribed herein.

These natural language synthesis steps may include using naturallanguage processing to evaluate the computer-readable code of theproposed upgrade and the computer-readable code of the infrastructureplatform(s) of the entity system 102 that are to be upgraded. Forexample, in some embodiments, the natural language synthesis application410 may be trained through machine-learning to parse executablecommands, permissions, database connections, compatibility information,and the like from computer-readable code. As an illustration, thenatural language synthesis application 410 may be provided with a seriesof computer-readable codes containing features such as executablecommands, permissions, database connections, compatibility information,and the like and given automatic and/or manual feedback on whether thenatural language synthesis application 410 has correctly identified thefeatures of the codes until the natural language synthesis application410 reliably identifies the features of a given set of code.

More specifically, as described in further detail below, the naturallanguage synthesis application 410 may, in some cases, identify theexecutable commands in the proposed upgrade code and the platform codeusing natural language processing, compare the commands used in theproposed upgrade code to the commands used in the platform code, anddetermine whether the commands of the proposed upgrade code match thecommands of the existing infrastructure platform. In some cases, thenatural language synthesis application 410 may identify the permissionsin the proposed upgrade code and the platform code using naturallanguage processing, compare the permissions used in the proposedupgrade code to the permissions used in the platform code, and determinewhether the permissions of the proposed upgrade code match thepermissions of the platform code. In some cases, the natural languagesynthesis application 410 may identify the database connections in theproposed upgrade code and the platform code using natural languageprocessing, compare the database connections used in the proposedupgrade code to the database connections used in the platform code, anddetermine whether the database connections of the proposed upgrade codematch the database connections of the platform code. In some cases, thenatural language synthesis application 410 may determine a list ofthird-party products included in the existing infrastructure platform(s)to be upgraded; for each third-party product, determine whether the sameversion, a lesser version, or a higher version of the third-partyproduct is included in the proposed upgrade; and if the same version orhigher version of one or more third-party products are included in theproposed upgrade, determine whether the one or more third-party productsare compatible with the code of the proposed upgrade.

Additionally, in some embodiments, the natural language synthesisapplication 410 is configured to build an execution plan or script usingnatural language processing. For example, in some cases, the naturallanguage synthesis application 410 may build the execution plan usingthe results of the evaluation of the proposed upgrade code and theplatform code (e.g., based on the results of comparing executablecommands, permissions, external database connections, andcompatibilities between the proposed upgrade code and the platformcode). More specifically, the natural language synthesis application 410may use the results of the evaluation to determine steps that should beperformed to successfully deploy the proposed upgrade. The naturallanguage synthesis application 410 is further configured to execute theexecution plan to simulate deploying the proposed upgrade and assess theoutput of the simulation for success.

Based on the output of the simulation, the natural language synthesisapplication 410 may also generate a report that includes instructions ondeploying the proposed upgrade. For example, the deployment report mayinclude one or more recommended actions that the deployment evaluationsystem 104, the entity system 102, and/or a user should carry out toensure that the deployment of the proposed upgrade is successful. Theseactions may include issues identified in the proposed upgrade thatshould be fixed before deployment, additional functionalities that thenatural language synthesis application 410 recommends adding to theproposed upgrade, one or more recommended scripts that would facilitatedeployment, and/or the like. In some cases, the natural languagesynthesis application 410 may be trained, using machine-learning and/orusing preprogrammed phrases, to generate the report in plain languagesuch that the report can be understood and followed by an individual whois not necessarily an expert in building and upgrading infrastructureplatforms. This may be beneficial for the entity, as a report written inplain language may be followed by an employee with relatively lessexperience, thereby freeing up more experienced build engineers anddevelopers may work on more complicated systems requiring theirexpertise.

In some embodiments, the trust score application 412 may comprisecomputer-readable instructions associated with one or more steps forgenerating a trust score, or the computer-readable instructionsassociated with one or more data gathering steps can be stored in theprocessing datastore 418. The trust score application 412 may beembodied within the natural language synthesis application 410, theactive code segregator application 414, and/or the experiencesinterpreter application 416, in some instances, or the natural languagesynthesis application 410, active code segregator application 414,and/or the experiences interpreter application 416 may be embodied inthe trust score application 412, in some instances. In some embodiments,the trust score application 412 comprises computer-readable instructionsthat, when executed by the processing device 404, cause the processingdevice 404 to perform one or more functions and/or transmit controlinstructions to other components or devices to perform the one or moresteps for generating a trust score.

These steps for generating a trust score may include using the resultsfrom the natural language synthesis application 410 to predict alikelihood of success in deploying the proposed upgrade and generate atrust score indicating that predicted likelihood of success. In someembodiments, the trust score application 412 may be configured togenerate the trust score by determining whether the proposed upgradecode meets a number of weighted criteria, where each weighted criterionis associated with a weighted value, and using the weighted values ofthe met criteria to generate the trust score. For example, the trustscore application 412 may determine the trust score based on whether theexecutable commands of the proposed upgrade compared to the executablecommands of the platform(s) to be upgraded meet certain criteria,whether the permissions of the proposed upgrade compared to thepermissions of the platform(s) meet certain criteria, whether theexternal database connections of the proposed upgrade compared to theexternal database connections of the platform(s) meet certain criteria,and whether third-party products used in the platform(s) will likely becompatible with the third-party products used in the proposed upgradeaccording to certain criteria.

In some embodiments, the active code segregator application 414 maycomprise computer-readable instructions associated with one or more codesegregation steps, or the computer-readable instructions associated withthe one or more code segregation steps may be stored in the processingdatastore 418. The active code segregator application 414 may beembodied within the natural language synthesis application 410, thetrust score application 412, and/or the experiences interpreterapplication 416, in some instances, or the natural language synthesisapplication 410, the trust score application 412, and/or the experiencesinterpreter application 416 may be embodied within the active codesegregator application 414, in some instances. In some embodiments, theactive code segregator application 414 comprises computer-readableinstructions that, when executed by the processing device 404, cause theprocessing device 404 to perform one or more functions and/or transmitcontrol instructions to other components or devices to perform the oneor more code segregation steps described herein.

These code segregation steps may include, in response to the trust scoreof a proposed upgrade being above a threshold, using natural languageprocessing to identify inactive code from active code in the existinginfrastructure platform(s) to be upgraded. In some embodiments, theactive code segregator application 414 may be trained through a similarmachine-learning process as used for the natural language synthesisapplication 410 to parse executable commands, permissions, databaseconnections, compatibility information, and the like fromcomputer-readable code. The active code segregator application 414 maythen use the parsed information to identify which scripts of theplatform code are active and which scripts of the platform code areinactive. For example, the active code segregator application 414 mayidentify scripts that are no longer linked by executable commands toactive code and are therefore inactive. As another example, the activecode segregator application 414 may determine, using information storedin the platform data 220 of the data repository 214 of the entity system102, whether each script of the platform code has been executed within acertain period of time, such as within the last five years. If a scripthas not been executed within the period of time, it may be classified asinactive.

The active code segregator application 414 may be further configured togenerate or build, or help generate or build, an automation script fordeploying the proposed upgrade. More specifically, the active codesegregator application 414 may be configured to generate, in whole or inpart, a script that executes the proposed upgrade onto theinfrastructure platform(s) to be upgraded while isolating sections ofinactive code of the platform(s) from the upgrade process such that theinactive code is not migrated to the upgraded platform(s). In somecases, the active code segregator application 414 may also use thedeployment report generated by the natural language synthesisapplication 410 in creating the automation script for deploying theproposed upgrade. For instance, the active code segregator application414 may use the report to determine a sequence of steps that should becarried out to successfully deploy the proposed upgrade. The active codesegregator application 414 may also use feedback and inputs from a buildengineer, which may also be prompted by the report, in creating theautomation script.

In some embodiments, the experiences interpreter application 416 maycomprise computer-readable instructions associated with one or moreexperience interpretation steps, or the computer-readable instructionsassociated with the one or more experience interpretation steps may bestored in the processing datastore 418. The experiences interpreterapplication 416 may be embodied within the natural language synthesisapplication 410, the trust score application 412, and/or the active codesegregator application 414, in some instances, or the natural languagesynthesis application 410, the trust score application 412, and/or theactive code segregator application 414 may be embodied within theexperiences interpreter application 416, in some instances. In someembodiments, the experiences interpreter application 416 comprisescomputer-readable instructions that, when executed by the processingdevice 404, cause the processing device 404 to perform one or morefunctions and/or transmit control instructions to other components ordevices to perform the one or more experience interpretation stepsdescribed herein.

These experience interpretation steps may include gathering informationon the results from the natural language synthesis application 410, thetrust score application 412, and the active code segregator application414 in order to refine one or more of these applications. In some cases,if the trust score for a proposed upgrade is below a certain threshold,the experiences interpreter application 416 may identify all failurecommands in the proposed upgrade, as well as associated scripts,parameters, configurations, and the like. The experiences interpreterapplication 416 may also run a repair process to fix some or all of theissues causing the low trust score. Similarly, if the trust score for aproposed upgrade is at or above a certain threshold but the proposedupgrade does not deploy successfully or deploys with one or more errors,the experiences interpreter application 416 may identify thepost-deployment errors, as well as the issues in the proposed upgradecode causing the post-deployment errors. On the other hand, if theproposed upgrade is deployed successfully, the experiences interpreterapplication 416 may identify functions, scripts, configurations, and thelike in the proposed upgrade that made the proposed upgrade successful.For example, the experiences interpreter application 416 may compare thesuccessful upgrade to previous, less successful upgrades in the past toidentify these successful functions, scripts, configurations, and thelike.

The experiences interpreter application 416 may then use thisinformation to help refine the natural language synthesis application410, the trust score application 412, and/or the active code segregatorapplication 414. As an illustration, the experiences interpreterapplication 416 may use gathered information to improve the naturallanguage processing of the natural language synthesis application 410 bytraining the natural language synthesis application 410 to betteridentify executable commands, permissions, external databaseconnections, and the like, or to prioritize the identification ofcertain executable commands, permissions, external database connections,and the like that have been associated with successful or unsuccessfulupgrade deployments. As another illustration, the experiencesinterpreter application 416 may use the information to refine theprocess by which the trust score application 412 generates the trustscore, such as by reweighing and/or modifying the criteria used todetermine the trust score.

It should be understood that while in FIGS. 1, 2, and 4, the entitysystem 102 and the deployment evaluation system 104 are shown asseparate systems, the entity system 102 and the deployment evaluationsystem 104 may, in some embodiments, be implemented partially orentirely as the same system. For example, the entity system 102 may beimplemented as a series of networked servers that also hostcomputer-readable code that performs the functions of the deploymentevaluation system 104 as described above and in further detail below.

These features will now be described with respect to the process flow500 of FIG. 5 and the process flow 600 of FIG. 6. Starting first withthe process flow 500 of FIG. 5, the deployment evaluation system 104first receives a proposed upgrade, as indicated by block 502. Forexample, the deployment evaluation system 104 may be directed by a userto a proposed upgrade stored in the proposed upgrade database 108. Afterreceiving the proposed upgrade, the deployment evaluation system 104performs a natural language synthesis of the proposed upgrade, asindicated by block 504. The synthesis may include using natural languageprocessing to evaluate various aspects, functions, commands, and thelike of the proposed upgrade compared to the infrastructure platform(s)to be upgraded. In some embodiments, the deployment evaluation system104 may be trained in using natural language processing as describedabove with reference to the natural language synthesis application 410of FIG. 4, such as by being trained using machine-learning to identifycertain aspects of computer-readable code.

In various embodiments, the natural language synthesis includesperforming the high-level process flow 600 of FIG. 6. Thus, in someembodiments, as part of performing the natural language synthesis, thedeployment evaluation system 104 may interpret and compare a list ofcommands used in the infrastructure platform(s) to be upgraded and alist of commands used in the proposed upgrade, as indicated by block602. In some cases, the deployment evaluation system 104 may compare thecommands used in the code of the proposed upgrade to the commands usedin the existing infrastructure platform(s), determine whether thecommands of the proposed upgrade code match the commands of the existinginfrastructure platform(s), and, if one or more commands of the proposedupgrade code do not match the commands of the platform(s), determine howfrequently the one or more non-matching commands are used in theproposed upgrade code. For example, the deployment evaluation system 104may determine in what number of scripts and in what percentage ofscripts of the proposed upgrade code a command that does not match acommand of the existing platform(s) is used.

As indicated by block 604, the deployment evaluation system 104 may alsoidentify and compare permissions in the existing infrastructureplatform(s) and the proposed upgrade. In some cases, the deploymentevaluation system 104 may compare commands used in the code of theproposed upgrade to commands used in the existing infrastructureplatform(s), determine whether permissions of the proposed upgradecommands match permissions of the existing platform commands, and, ifone or more permissions of the proposed upgrade commands do not matchthe permissions of the existing infrastructure platform commands,determine how frequently the one or more permissions are used in theproposed upgrade code. As an example, the deployment evaluation system104 may determine in what percentage of scripts of the proposed upgradecode a permission that does not match any of the permissions of theexisting platform(s) is used.

As indicated by block 606, the deployment evaluation system 104 mayfurther identify, test, and compare external database connections in theexisting infrastructure platform(s) and the proposed upgrade. In somecases, the deployment evaluation system 104 may compare databaseconnections in the code of the proposed upgrade to database connectionsin the existing infrastructure platform(s), determine whether thedatabase connections of the proposed upgrade code match the databaseconnections of the existing infrastructure platform, and, if one or moredatabase connections of the proposed upgrade code do not match thedatabase connections of the existing infrastructure platform(s),determine how many of the proposed upgrade code database connections donot match a database connection of the existing platform(s). Toillustrate, the deployment evaluation system 104 may determine whatpercentage of the external database connections of the proposed upgradedo not match any of the database connections of the existingplatform(s). In some cases, the deployment evaluation system 104 mayalso test each of the external database connections of the proposedupgrade to determine if the external databases are correctly working andresponding.

As indicated by block 608, the deployment evaluation system 104 mayadditionally perform a compatibility check between the existinginfrastructure platform(s) and the proposed upgrade. In some cases, thedeployment evaluation system 104 may determine a list of third-partyproducts that are included on the existing infrastructure platform(s)and, for each third-party product, determine whether the same version, alesser version, or a higher version of the third-party product isincluded in the proposed upgrade. If the same version or a higherversion of one or more third-party products is included in the proposedupgrade, the deployment evaluation system 104 may determine whether theone or more third-party products are compatible with the code of theproposed upgrade. Further, if at least one of the one or morethird-party products is not compatible with the code of the proposedupgrade, the deployment evaluation system 104 may determine howfrequently the at least one third-party product is used in the proposedupgrade code compared to how frequently the at least one third-partyproduct is used in the existing infrastructure platform. For example,the deployment evaluation system 104 may determine whether eachnon-compatible product is used more frequently or less frequently in theproposed upgrade compared to the platform(s) to be upgraded.

As indicated by block 610, the deployment evaluation system 104 may thenbuild a natural language processing execution plan. The deploymentevaluation system 104 may use the natural language processing executionplan to simulate the deployment of the proposed upgrade. In someembodiments, the deployment evaluation system 104 may use the results ofblocks 602, 604, 606, and 608 to build the execution plan. For example,the deployment evaluation system 104 may determine executable scriptsthat should be evaluated, permissions that should be tested, externaldatabase connections that should be tested, and compatibilities thatshould be tested based on the results of blocks 602, 604, 606, and 608.The deployment evaluation system 104 may also determine steps or scriptsthat should be executed in order to potentially deploy the proposedupgrade to the infrastructure platform(s) to be upgraded.

As indicated by block 612, the deployment evaluation system 104 mayaccordingly execute the natural language processing execution plan. Asan illustration, this may include testing executable commands of theproposed upgrade code to determine whether they produce a desiredresult, testing permissions of the proposed upgrade code to determinewhether they are working, testing external database connections to makesure the databases are working correctly and responding to the proposedupgrade code, determining whether versions of third-party productsincluded in the platform(s) and the proposed upgrade are compatible witheach other, and/or the like. The deployment evaluation system 104 mayalso analyze the results of the execution plan to determine to whatextent the simulation of the proposed upgrade was successful. Thedeployment evaluation system 104 may further analyze the results of theexecution plan to determine what improvements could be made to theproposed upgrade code to maximize the chances of its deployment beingsuccessful.

Returning to the process flow 500, after performing the natural languagesynthesis as discussed above, the deployment evaluation system 104generates a deployment report, as indicated by block 508. In someembodiments, the deployment report may include steps for improving theproposed upgrade and/or steps for deploying the proposed upgrade.Further, in some cases, the report may include the results of thenatural language processing execution plan and any proposed improvementsto the proposed upgrade code determined at block 612 of the process flow600. In some embodiments, the deployment evaluation system 104 may alsogenerate the report in plain, less technical language. For example, thedeployment evaluation system 104 may use preprogrammed phrases orsentences that depend on various proposals and outcomes of the executionplan, and/or the deployment evaluation system 104 may usemachine-learning to develop natural language for the report. Asindicated by block 508, the deployment evaluation system 104 thentransmits the report to a build engineer. For example, the deploymentevaluation system 104 may generate a GUI or a series of GUIs fordisplaying the report that the deployment evaluation system 104transmits to the user device 106. As another example, the deploymentevaluation system 104 may email the report to the build engineer thatsubmitted the proposed upgrade.

Additionally, after performing the natural language synthesis, thedeployment evaluation system 104 generates a trust score for theproposed upgrade, as indicated by block 510. In some embodiments, thedeployment evaluation system 104 generates the trust score by using theresults of the natural language synthesis to determine whether theproposed upgrade meets various weighted criteria, where each criterionis associated with a numerical value. The numerical values of the metweighted criteria are then used to determine the trust score.

To illustrate, in some embodiments, the deployment evaluation system 104may evaluate the proposed upgrade relative to several sets of criteria.For instance, the deployment evaluation system 104 may evaluate whetherthe proposed upgrade meets a first set of criteria relating to theexecutable commands of the proposed upgrade. If the executable commandsused in the proposed upgrade are the same as the executable commandsused in the platform(s) to be upgraded, the deployment evaluation system104 may assign a full score for the first set of criteria (e.g., “valueA”). If one or more executable commands used in the proposed upgrade arenot the same as the executable commands of the platform(s), thedeployment evaluation system 104 may instead determine how frequentlythe non-matching executable command(s) are used in the proposed upgrade.

More specifically, as an example, if only one command of the proposedupgrade is non-matching, and the one non-matching command is used inless than a certain percentage of the proposed upgrade scripts and lessthan a certain number of the proposed upgrade scripts, the deploymentevaluation system 104 may assign a “value B” score for the first set ofcriteria. If the non-matching command is used in the certain percentageor more than the certain percentage of proposed upgrade scripts and/oris used in the certain number or more than the certain number ofproposed upgrade scripts, the deployment evaluation system 104 mayassign a “value C” score for the first set of criteria. If two commandsof the proposed upgrade are non-matching, and the two non-matchingcommands are used in less than the certain percentage of proposedupgrade scripts and less than the certain number of the proposed upgradescripts, the deployment evaluation system 104 may assign a “value D”score for the first set of criteria. If the two non-matching commandsare used in the certain percentage or more than the certain percentageof proposed upgrade scripts and/or the certain number or more than thecertain number of proposed upgrade scripts, the deployment evaluationsystem 104 may assign a “value E” score for the first set of criteria.If, instead, more than two of the commands of the proposed upgrade arenon-matching commands, and the non-matching commands are used in lessthan the certain percentage of proposed upgrade scripts and less thanthe certain number of proposed upgrade scripts, the deploymentevaluation system 104 may assign a “value F” score for the first set ofcriteria. If the non-matching commands are otherwise used in the certainpercentage or more than the certain percentage of proposed upgradescripts and/or the certain number or more than the certain number ofproposed upgrade scripts, the deployment evaluation system 104 mayassign a “value G” score for the first set of criteria. The value A-Gscores may be configured such that they decrease in value, such aslinearly or in a stepwise fashion. For instance, value A may be thehighest score, value G may be the lowest score, value C may be the sameas value D, value E may be the same as value F, and so on.

The deployment evaluation system 104 may also evaluate whether theproposed upgrade meets a second set of criteria relating to thepermissions of the proposed upgrade. If the permissions used in theproposed upgrade are the same as the permissions used in the platform(s)to be upgraded, the deployment evaluation system 104 may assign a fullscore for the second set of criteria (e.g., “value H”). If thepermissions used in the proposed upgrade are not the same as thepermissions of the platform(s), the deployment evaluation system 104 mayinstead determine how frequently the non-matching permission(s) are usedin the proposed upgrade. As an example, if less than a first thresholdof scripts use at least one non-matching permission, the deploymentevaluation system 104 may assign a “value I” score for the second set ofcriteria. If between the first threshold and a second, higher thresholdof scripts use at least one non-matching permission, the deploymentevaluation system 104 may assign a “value J” score for the second set ofcriteria. If between the second threshold and a third, higher thresholdof scripts use at least one non-matching permission, the deploymentevaluation system 104 may assign a “value K” score for the second set ofcriteria. Finally, if more than the third threshold of scripts use atleast one non-matching permission, the deployment evaluation system 104may assign a “value L” score for the second set of criteria. The valueH-L scores may be configured, for example, such that they decrease in alinear or exponential fashion.

The deployment evaluation system 104 may further evaluate whether theproposed upgrade meets a third set of criteria relating to the externaldatabase connections of the proposed upgrade. If the databaseconnections used in the proposed upgrade are the same as the databaseconnections used in the platform(s) to be upgraded, the deploymentevaluation system 104 may assign a full score for the third set ofcriteria (e.g., “value M”) for the third set of criteria. If thedatabase connections used in the proposed upgrade are not the same asthe database connections of the platform(s), the deployment evaluationsystem 104 may instead determine a ratio of the database connections inthe proposed upgrade that do not match any of the database connectionsin the platform(s) to the total number of database connections in theproposed upgrade. For instance, if less than a first percentage of theproposed upgrade database connections are non-matching, the deploymentevaluation system 104 may assign a “value N” score for the third set ofcriteria. If between the first percentage and a second, higherpercentage of proposed upgrade database connections are non-matching,the deployment evaluation system 104 may assign a “value O” score forthe third set of criteria. If between the second percentage and a third,higher percentage of proposed upgrade database connections arenon-matching, the deployment evaluation system 104 may assign a “valueP” score for the third set of criteria. Finally, if more than the thirdpercentage of proposed upgrade database connections are non-matching,the deployment evaluation system 104 may assign a “value Q” score forthe third set of criteria. The value M-Q scores may be configured, forexample, such that they decrease in a linear or exponential fashion,similar to the value H-L scores. In some implementations, the deploymentevaluation system 104 may also test the database connections and count anon-working database connection as a “non-matching” connection for thepurposes of determining the trust score.

In addition, the deployment evaluation system 104 may evaluate whetherthird-party products used in the proposed upgrade are compatible withthird-party products used in the platform(s) to be upgraded as part of afourth set of criteria. As an example, the deployment evaluation system104 may determine a list of the third-party products included in theexisting infrastructure platform(s) to be upgraded and a list of thethird-party products included in the proposed upgrade. These lists maycontain, for instance, all software and clients installed on theexisting platform(s) and all software and clients to be included in theproposed upgrade. In some cases, the third-party software products mayinclude software products created by the entity that have differentversions and may exist separately or may be separately built onto theexisting infrastructure platform(s) in addition to software productsreleased by groups other than the entity. The deployment evaluationsystem 104 may then compare the third-party products of the platform(s)and the proposed upgrade to determine whether the same version, a lesserversion, or a higher version of each third-party product used in theplatform(s) is included in the proposed upgrade.

If the same version for each third-party product is installed in theproposed upgrade, then the deployment evaluation system 104 may verifywhether the third-party products of the platform(s) are compatible withthe third-party products of the proposed upgrade. If all third-partyproducts are compatible, the deployment evaluation system 104 may assigna full score for the fourth set of criteria (e.g., “value R”). If one ormore of the third-party products of the platform(s) are not compatiblewith the third-party products of the proposed upgrade, the deploymentevaluation system 104 may determine whether the one or more third-partyproducts are used more frequently in the proposed upgrade compared theiruse in the existing platform(s). If the one or more third-party productsare used less frequently in the proposed upgrade, the deploymentevaluation system 104 may assign a “value S” score for the fourth set ofcriteria. If, instead, the one or more third-party products are usedmore frequently in the proposed upgrade, the deployment evaluationsystem 104 may assign a “value T” score for the fourth set of criteria.

The deployment evaluation system 104 may make similar determinations ifa higher version for one or more of the third-party products isinstalled in the proposed upgrade. As such, the deployment evaluationsystem 104 may determine whether the third-party products of theplatform(s) are compatible with the third-party products of the proposedupgrade. If all third-party products are compatible, the deploymentevaluation system 104 may assign the full value R score for the fourthset of criteria. If one or more of the third-party products of theplatform(s) are not compatible, the deployment evaluation system 104 maythen determine if the non-compatible product(s) are used more frequentlyin the proposed upgrade compared to their use in the existingplatform(s). If the one or more third-party products are used lessfrequently in the proposed upgrade, the deployment evaluation system 104may assign a “value U” score for the fourth set of criteria, while ifthe one or more third-party products are instead used more frequently inthe proposed upgrade, the deployment evaluation system 104 may insteadassign a higher “value V” score for the fourth set of criteria. In somecases, the value S score may be the same as the value U score, and thevalue T score may be the same as the value V score.

On the other hand, if the deployment evaluation system 104 determinesthat a lesser version of at least one third-party product of theplatform(s) is installed in the proposed upgrade, or if at least onethird-party product of the platform(s) is missing from the proposedupgrade, the deployment evaluation system 104 may assign a minimum“value W” score for the fourth set of criteria, such as a score of zero.In some cases, the value R-W scores may be configured such that theydecrease, for example, linearly or exponentially.

Once the deployment evaluation system 104 determines which criterionfrom each set of weighted criteria the proposed update meets, thedeployment evaluation system 104 uses the assigned values from the metcriteria to determine the trust score, such as by summing the assignedvalues to produce the trust score. In some cases, the numerical valuesassigned for the various criteria are configured such that each set ofcriteria is weighted compared to the other sets of criteria. As anexample, values A-G may be scored out of 100 but then multiplied by aweight such that the assigned value only comprises, for instance, 20% ofthe trust score. For example, the first set of criteria may make up 20%of the trust score, the second set of criteria may make up 10% of thetrust score, the third set of criteria may make up 30% of the trustscore, and the fourth set of criteria may make up 40% of the trustscore.

Once the deployment evaluation system 104 has generated the trust scorefor the proposed upgrade, the deployment evaluation system 104determines whether the trust score is above (or, in some cases, equal toor above) a certain threshold, as indicated by block 512. For example,the threshold may be set to ensure that only proposed upgrades with ahigh likelihood of success are deployed. If the trust score is below thethreshold, the deployment evaluation system 104 may perform a repairprocess, as indicated by block 514. The repair process may includecataloguing issues in the proposed upgrade that were identified from thethe natural language synthesis and/or generation of the trust score. Toillustrate, the deployment evaluation system 104 may identify all failedcommands and their respective scripts, parameters, configurations, andthe like that are present on the proposed upgrade and/or platform(s) tobe upgraded. In some cases, for instance, the deployment evaluationsystem 104 may identify why the proposed upgrade met certain criteriaused to generate the trust score. The deployment evaluation system 104may then attempt to repair these issues and/or transmit a list of theissues to a build engineer. As an example, if the proposed upgradescored poorly because the proposed upgrade includes permissions that arenot present in the existing platform(s), the deployment evaluationsystem 104 may verify that each of the permissions added to the proposedupgrade is working correctly and therefore should not pose an issue whenthe platform(s) are upgraded.

On the other hand, if the trust score is above the threshold, thedeployment evaluation system 104 determines whether the platform(s) tobe upgraded include inactive code, as indicated by block 516. In someembodiments, as discussed above with reference to the active codesegregator application 414 of FIG. 4, the deployment evaluation system104 may use natural language processing to identify scripts, executablecommands, and the like that are inactive and/or have not been used for acertain period of time. If the platform(s) contain inactive code, thedeployment evaluation system 104 may isolate the active code from theinactive code, as indicated by block 518. For example, the deploymentevaluation system 104 may identify sections of active code that shouldbe migrated to the new environment when the platform(s) are upgraded bythe proposed upgrade, as opposed to sections of inactive code thatshould not be moved over with the upgrade.

After isolating the active code, the deployment evaluation system 104generates or builds an automation script for deploying the proposedupgrade to create an upgraded infrastructure platform or platforms, asindicated by block 520. Alternatively, if the platform(s) do not includeinactive code, the deployment evaluation system 104 may proceed directlyto generating the automation script at block 520. Generating theautomation script may include incorporating steps, improvements, and thelike that were identified in the deployment report created at block 506.For example, the deployment evaluation system 104 may automatically addto or update the proposed upgrade according to the proposed steps,improvements, and the like in the report. In some cases, the deploymentevaluation system 104 may also receive feedback from a build engineerthat the deployment evaluation system 104 incorporates into theautomation script, as indicated by block 522. As an illustration, abuild engineer, who may or may not be the same build engineer whoreceived the deployment report at block 508, may provide updatedproposed upgrade code that includes the proposed improvements indicatedin the report to the deployment evaluation system 104. In some cases,the build engineer may also create the automation script, at least inpart, based on the report, such as based on the deployment steps for theproposed upgrade outlined in the report. If applicable, the deploymentevaluation system 104 further generates the build automation script suchthat the inactive code isolated at block 518 will be excluded when theproposed upgrade is executed. Thus, the upgraded infrastructureplatform(s) created from the proposed upgrade should include a minimumof inactive code.

As indicated by block 524, the deployment evaluation system 104 thenexecutes the build automation script to attempt to deploy the proposedupgrade and create the upgraded infrastructure platform(s). As indicatedby block 526, the deployment evaluation system 104 determines whetherthe deployment of the proposed upgrade was successful. If the deploymentwas successful, the deployment evaluation system 104 may capture andinterpret the experiences of the process for evaluating and deployingthe proposed upgrade, as indicated by block 530. For instance, thedeployment evaluation system 104 may determine one or more parametersrelating to the successful deployment, such as the steps, the scripts,the executable commands, the permissions, and the like of the proposedupgrade that made the proposed upgrade successful. This may includecomparing the proposed upgrade to previous, less successful upgrades.

If the deployment was not successful, including if the proposed upgradewas able to be carried out but incurred at least some post-deploymenterrors, the deployment evaluation system 104 identifies thepost-deployment errors, as indicated by block 528. At block 530, thedeployment evaluation system 104 then uses the post-deployment errors tocapture and interpret the experiences of unsuccessfully or partiallysuccessfully launching the proposed upgrade. To illustrate, thedeployment evaluation system 104 may determine one or more parametersthat caused the errors (e.g., executable commands being unable to becarried out, denied permissions, issues with connecting to externaldatabases, compatibility issues, and/or the like) and how these errorscould be prevented in the future. As shown in FIG. 5, the deploymentevaluation system 104 also makes a similar determination for a proposedupgrade in response to the trust score being below the threshold atblock 512 and the repair process being performed at block 514. Forexample, the deployment evaluation system 104 may identify one or moreparameters that caused the trust score to be below the threshold andsteps, scripts, executable commands, permissions and the like associatedwith the parameters causing the low trust score.

As indicated by block 532, the deployment evaluation system 104 refinesvarious blocks of the process flow 500, including the natural languagesynthesis performed at block 504, the trust score generated at block510, and/or the active/inactive code isolation process performed atblock 518. In some cases, for instance, the deployment evaluation system104 may use the experiences captured and interpreted at block 530 totrain the deployment evaluation system 104 to more accurately identifypieces and/or functionalities of code as part of the natural languagesynthesis. The deployment evaluation system 104 may also uses theseexperiences to focus the natural language synthesis on the components ofa proposed upgrade that are shown by the experiences to be more likelyto cause failure or cause success than other components. In some cases,the deployment evaluation system 104 may use the experiences of block530 to reweigh and/or change the criteria used to determine the trustscore. For example, the deployment evaluation system 104 may identifyproposed upgrade functionalities or lack of functionalities that aremore likely to cause a successful or unsuccessful platform upgrade. Thedeployment evaluation system 104 may then reweigh the criteria used togenerate the trust score such that the deployment evaluation system 104assigns higher trust scores to proposed upgrades that includefunctionalities that have been present in historically successfulupgrades and lower trust scores to proposed upgrades that lack thefunctionalities present in historically successful upgrades and/orinclude components or functionalities that have been present inhistorically unsuccessful upgrades. In some cases, the deploymentevaluation system 104 may use the experiences of block 530 to determinehow effectively the deployment evaluation system 104 migrated activecode with the proposed upgrade while isolating away inactive code. Forexample, the deployment evaluation system 104 may determine, usingnatural language synthesis, whether the upgraded platform(s) includeexecutable commands that do not perform functions. As another example,the deployment evaluation system 104 may determine, from post-deploymenterrors, whether the upgraded platform(s) are missing executable commandsbased on broken links from other scripts. The deployment evaluationsystem 104 may use this data to improve the process of identifyinginactive code accordingly.

It should be understood that the process flows 500 and 600 are intendedto be exemplary and that other processes may be used to synthesize aproposed upgrade, generate a trust score, isolate inactive code fromactive code, execute the proposed upgrade, and capture and interpret theexperiences of the upgrade. For instance, the trust score may begenerated using different criteria than the exemplary criteria discussedabove. Alternatively, the trust score may be generated using a differentprocess, such as by quantifying various aspects of the proposed upgradecode (e.g., counting the number of executable commands, permissions,external database connections, and/or the like), determining alikelihood that the various aspects will be successfully implemented inthe upgrade, multiplying the likelihood of each aspect by thequantification for each aspect, and summing the results.

FIG. 7 illustrates a representation of a GUI 700 for display on a userdevice (e.g., the user device 106), in accordance with some embodimentsof the invention. For example, the user may request to view the GUI 700to understand why a proposed upgrade received a certain trust score.Alternatively, the GUI 700 may be included in a deployment reportgenerated by the deployment evaluation system 104. The example GUI 700includes a header 702 identifying the proposed upgrade. The GUI 700 thenincludes the trust score for the proposed upgrade in a sub-header 704.Underneath the sub-header 704 is a breakdown 706 of the trust score. Forinstance, as shown, the breakdown 706 may include a list of differentsets of criteria used to determine the trust score (e.g., in FIG. 7, afirst set of criteria listed under “Trust Score Section 1”, a second setof criteria listed under “Trust Score Section 2”, a third set ofcriteria listed under “Trust Score Section 3”, and the like). Thecriterion for each set that the proposed upgrade meets is bolded, alongwith the score associated with the criterion. The breakdown 706 alsoincludes a running total of the overall score for the proposed upgrade.As such, the GUI 700 demonstrates to the user why the proposed upgradereceived the trust score that it did. The user may be able to scrolldown the GUI 700 to see all of the criteria and scores assigned to theproposed upgrade.

It should be understood that the GUI 700 illustrated in FIG. 7 isintended to be exemplary. Additional and alternative GUIs may begenerated by the deployment evaluation system 104 and displayed by auser device 106 to communicate information about the natural languagesynthesis, the trust score, the captured experiences, and/or the like.

As will be appreciated by one of ordinary skill in the art, the presentinvention may be embodied as an apparatus (including, for example, asystem, a machine, a device, a computer program product, and/or thelike), as a method (including, for example, a business process, acomputer-implemented process, and/or the like), or as any combination ofthe foregoing. Accordingly, embodiments of the present invention maytake the form of an entirely software embodiment (including firmware,resident software, micro-code, and the like), an entirely hardwareembodiment, or an embodiment combining software and hardware aspectsthat may generally be referred to herein as a “system.” Furthermore,embodiments of the present invention may take the form of a computerprogram product that includes a computer-readable storage medium havingcomputer-executable program code portions stored therein. As usedherein, a processor may be “configured to” perform a certain function ina variety of ways, including, for example, by having one or morespecial-purpose circuits perform the functions by executing one or morecomputer-executable program code portions embodied in acomputer-readable medium and/or having one or more application-specificcircuits perform the function.

It will be understood that any suitable computer-readable medium may beutilized. The computer-readable medium may include, but is not limitedto, a non-transitory computer-readable medium, such as a tangibleelectronic, magnetic, optical, infrared, electromagnetic, and/orsemiconductor system, apparatus, and/or device. For example, in someembodiments, the non-transitory computer-readable medium includes atangible medium such as a portable computer diskette, a hard disk, arandom access memory (RAM), a read-only memory (ROM), an erasableprogrammable read-only memory (EPROM or Flash memory), a compact discread-only memory (CD-ROM), and/or some other tangible optical and/ormagnetic storage device. In other embodiments of the present invention,however, the computer-readable medium may be transitory, such as apropagation signal including computer-executable program code portionsembodied therein.

It will also be understood that one or more computer-executable programcode portions for carrying out the specialized operations of the presentinvention may be required on the specialized computer includeobject-oriented, scripted, and/or unscripted programming languages, suchas, for example, Java, Perl, Smalltalk, C++, SAS, SQL, Python, ObjectiveC, and/or the like. In some embodiments, the one or morecomputer-executable program code portions for carrying out operations ofembodiments of the present invention are written in conventionalprocedural programming languages, such as the “C” programming languagesand/or similar programming languages. The computer program code mayalternatively or additionally be written in one or more multi-paradigmprogramming languages, such as, for example, F#.

It will further be understood that some embodiments of the presentinvention are described herein with reference to flowchart illustrationsand/or block diagrams of systems, methods, and/or computer programproducts. It will be understood that each block included in theflowchart illustrations and/or block diagrams, and combinations ofblocks included in the flowchart illustrations and/or block diagrams,may be implemented by one or more computer-executable program codeportions. These one or more computer-executable program code portionsmay be provided to a processor of a special purpose computer for thecontinuous authentication and encryption processes and/or some otherprogrammable data processing apparatus in order to produce a particularmachine, such that the one or more computer-executable program codeportions, which execute via the processor of the computer and/or otherprogrammable data processing apparatus, create mechanisms forimplementing the steps and/or functions represented by the flowchart(s)and/or block diagram block(s).

It will also be understood that the one or more computer-executableprogram code portions may be stored in a transitory or non-transitorycomputer-readable medium (e.g., a memory, and the like) that can directa computer and/or other programmable data processing apparatus tofunction in a particular manner, such that the computer-executableprogram code portions stored in the computer-readable medium produce anarticle of manufacture, including instruction mechanisms which implementthe steps and/or functions specified in the flowchart(s) and/or blockdiagram block(s).

The one or more computer-executable program code portions may also beloaded onto a computer and/or other programmable data processingapparatus to cause a series of operational steps to be performed on thecomputer and/or other programmable apparatus. In some embodiments, thisproduces a computer-implemented process such that the one or morecomputer-executable program code portions which execute on the computerand/or other programmable apparatus provide operational steps toimplement the steps specified in the flowchart(s) and/or the functionsspecified in the block diagram block(s). Alternatively,computer-implemented steps may be combined with operator and/orhuman-implemented steps in order to carry out an embodiment of thepresent invention.

While certain exemplary embodiments have been described and shown in theaccompanying drawings, it is to be understood that such embodiments aremerely illustrative of, and not restrictive of, the broad invention, andthat this invention not be limited to the specific constructions andarrangements shown and described, since various other changes,combinations, omissions, modifications and substitutions, in addition tothose set forth in the above paragraphs, are possible. Those skilled inthe art will appreciate that various adaptations and modifications ofthe just described embodiments can be configured without departing fromthe scope and spirit of the invention. Therefore, it is to be understoodthat, within the scope of the appended claims, the invention may bepracticed other than as specifically described herein.

1. A system for synthesizing and building infrastructure platforms, thesystem comprising: a memory device with computer-readable program codestored thereon; a communication device; and a processing deviceoperatively coupled to the memory device and communication device,wherein the processing device is configured to execute thecomputer-readable program code to: perform a natural language synthesisof a proposed upgrade to one or more existing infrastructure platforms,wherein the natural language synthesis comprises analyzing, usingnatural language processing, code of the proposed upgrade by: comparingdatabase connections in the code of the proposed upgrade to databaseconnections in the one or more existing infrastructure platforms;determining whether the database connections of the proposed upgradecode match the database connections of the one or more existinginfrastructure platforms; and if one or more database connections of theproposed upgrade code do not match the database connections of the oneor more existing infrastructure platforms, determining a ratio of theone or more database connections to a total number of databaseconnections of the proposed upgrade code; generate a trust score fromresults of the natural language synthesis, wherein the trust scoreindicates a predicted likelihood of success for the proposed upgrade; inresponse to the trust score being above a threshold, identify, usingnatural language processing, inactive code in the one or more existinginfrastructure platforms; generate a build automation script fordeploying the proposed upgrade to create one or more upgradedinfrastructure platforms that exclude the inactive code; execute thebuild automation script to simulate development of the proposed upgradeincluding one or more of: testing executable commands, testingpermissions, and/or testing external database connections; capture datafrom a result of the build automation script execution; and use theresult of the build automation script execution and the captured data torefine the natural language synthesis to generate a deployment report inplain language.
 2. The system of claim 1, wherein the processing deviceis further configured to: build an execution plan from the results ofthe natural language synthesis; and generate a report from the executionplan, wherein the report includes instructions on deploying the proposedupgrade written in plain language, and wherein the build automationscript is at least partially based on the report.
 3. The system of claim1, wherein generating the trust score from the results of the naturallanguage synthesis comprises: determining, based on the results of thenatural language synthesis, whether the code of the proposed upgrademeets a plurality of weighted criteria, wherein each weighted criterionis associated with a weighted value; and using the weighted values ofthe met criteria to generate the trust score.
 4. The system of claim 1,wherein capturing the data from the result of the build automationscript execution comprises, in response to one or more post-deploymenterrors in the deployment of the proposed upgrade, capturing the one ormore post-deployment errors and one or more parameters of the proposedupgrade that caused the one or more post-deployment errors.
 5. Thesystem of claim 1, wherein capturing the data from the result of thebuild automation script execution comprises, in response to thedeployment of the proposed upgrade being a success, capturing one ormore parameters of the proposed upgrade relating to the success.
 6. Acomputer-implemented method for synthesizing and building infrastructureplatforms, the method comprising: performing a natural languagesynthesis of a proposed upgrade to one or more existing infrastructureplatforms, wherein the natural language synthesis comprises analyzing,using natural language processing, code of the proposed upgrade by:comparing database connections in the code of the proposed upgrade todatabase connections in the one or more existing infrastructureplatforms; determining whether the database connections of the proposedupgrade code match the database connections of the one or more existinginfrastructure platforms; and if one or more database connections of theproposed upgrade code do not match the database connections of the oneor more existing infrastructure platforms, determining a ratio of theone or more database connections to a total number of databaseconnections of the proposed upgrade code; generating a trust score fromresults of the natural language synthesis, wherein the trust scoreindicates a predicted likelihood of success for the proposed upgrade; inresponse to the trust score being above a threshold, identifying, usingnatural language processing, inactive code in the one or more existinginfrastructure platforms; generating a build automation script fordeploying the proposed upgrade to create one or more upgradedinfrastructure platforms that exclude the inactive code; executing thebuild automation script to simulate development of the proposed upgradeincluding one or more of: testing executable commands, testingpermissions, and/or testing external database connections; capturingdata from a result of the build automation script execution; and usingthe result of the build automation script execution and the captureddata to refine the natural language synthesis to generate a deploymentreport in plain language.
 7. The computer-implemented method of claim 6,further comprising: building an execution plan from the results of thenatural language synthesis; and generating a report from the executionplan, wherein the report includes instructions on deploying the proposedupgrade written in plain language, and wherein the build automationscript is at least partially based on the report.
 8. Thecomputer-implemented method of claim 6, wherein generating the trustscore from the results of the natural language synthesis comprises:determining, based on the results of the natural language synthesis,whether the code of the proposed upgrade meets a plurality of weightedcriteria, wherein each weighted criterion is associated with a weightedvalue; and using the weighted values of the met criteria to generate thetrust score.
 9. The computer-implemented method of claim 6, whereincapturing the data from the result of the build automation scriptexecution comprises, in response to one or more post-deployment errorsin the deployment of the proposed upgrade, capturing the one or morepost-deployment errors and one or more parameters of the proposedupgrade that caused the one or more post-deployment errors.
 10. Thecomputer-implemented method of claim 6, wherein capturing the data fromthe result of the build automation script execution comprises, inresponse to the deployment of the proposed upgrade being a success,capturing one or more parameters of the proposed upgrade relating to thesuccess.
 11. A computer program product for synthesizing and buildinginfrastructure platforms with at least one non-transitorycomputer-readable medium having computer-readable program code portionsembodied therein, the computer-readable program code portionscomprising: an executable portion configured for performing a naturallanguage synthesis of a proposed upgrade to one or more existinginfrastructure platforms, wherein the natural language synthesiscomprises analyzing, using natural language processing, code of theproposed upgrade by: comparing database connections in the code of theproposed upgrade to database connections in the one or more existinginfrastructure platforms; determining whether the database connectionsof the proposed upgrade code match the database connections of the oneor more existing infrastructure platforms; and if one or more databaseconnections of the proposed upgrade code do not match the databaseconnections of the one or more existing infrastructure platforms,determining a ratio of the one or more database connections to a totalnumber of database connections of the proposed upgrade code; anexecutable portion configured for generating a trust score from resultsof the natural language synthesis, wherein the trust score indicates apredicted likelihood of success for the proposed upgrade; an executableportion configured for, in response to the trust score being above athreshold, identifying, using natural language processing, inactive codein the one or more existing infrastructure platforms; an executableportion configured for generating a build automation script fordeploying the proposed upgrade to create one or more upgradedinfrastructure platforms that exclude the inactive code; an executableportion configured for executing the build automation script to simulatedevelopment of the proposed upgrade including one or more of: testingexecutable commands, testing permissions, and/or testing externaldatabase connections; an executable portion configured for capturingdata from a result of the build automation script execution; and anexecutable portion configured for using the result of the buildautomation script execution and the captured data to refine the naturallanguage synthesis to generate a deployment report in plain language.12. The computer-program product of claim 11, wherein thecomputer-readable program code portions further comprise: an executableportion configured for building an execution plan from the results ofthe natural language synthesis; and an executable portion configured forgenerating a report from the execution plan, wherein the report includesinstructions on deploying the proposed upgrade written in plainlanguage, and wherein the build automation script is at least partiallybased on the report.
 13. The computer-program product of claim 11,wherein the computer-readable program code portions further comprise: anexecutable portion configured for determining, based on the results ofthe natural language synthesis, whether the code of the proposed upgrademeets a plurality of weighted criteria, wherein each weighted criterionis associated with a weighted value; and an executable portionconfigured for using the weighted values of the met criteria to generatethe trust score.
 14. The computer-program product of claim 11, whereinthe executable portion configured for capturing the data from the resultof the build automation script execution comprises, in response to oneor more post-deployment errors in the deployment of the proposedupgrade, and an executable portion capturing the one or morepost-deployment errors and one or more parameters of the proposedupgrade that caused the one or more post-deployment errors.
 15. Thecomputer-program product of claim 11, wherein capturing the data fromthe result of the build automation script execution comprises, inresponse to the deployment of the proposed upgrade being a success,capturing one or more parameters of the proposed upgrade relating to thesuccess.